US6388983B1

US6388983B1 - Clamp mechanism for disk drive

Info

Publication number: US6388983B1
Application number: US09/415,820
Authority: US
Inventors: Hideo Kikuchi
Original assignee: Alps Electric Co Ltd
Current assignee: Alps Alpine Co Ltd
Priority date: 1998-10-12
Filing date: 1999-10-12
Publication date: 2002-05-14
Anticipated expiration: 2019-10-12
Also published as: JP2000123452A

Abstract

In the conventional clamp mechanism for a disk drive, since a clamper is attracted by a magnetic plate in a non-clamped state of the disk D, when the disk drive receives vibrations or shocks, the clamper is released from attraction by the magnetic plate to create displacement of the clamper. Since, in the clamp mechanism for a disk drive of the present invention, the holding arm lifts up the clamper and maintains a lifted-up state of the clamper in the non-clamped state of the disk D, the vibrations or shocks received by the disk drive will not cause displacement of the clamper.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a clamp mechanism for a disk drive suitable for use in an optical disk drive and the like.

2. Description of the Prior Art

A clamp mechanism for a conventional disk drive will be explained with reference to FIG. 10 and FIG. 11. A support member 51 is comprised of a chassis 52 including a hole 52 a on the center thereof and a bent part 52 b with a section of L-letter shape, and a support plate 53 having a magnetic plate 63, fixed to the chassis 52 so as to cover an upper hole of the chassis 52.

And, between the chassis 52 and the support plate 53 is made up a housing space 54.

A clamper 55 is comprised of a clamping part 55 a made of a synthetic resin being a non-magnetic material, a neck part 55 b formed integrally with the clamping part 55 a, which has a smaller diameter than the clamping part 55 a, a flange part 55 c affixed to the neck part 55 b, and a magnet 56 placed inside thereof.

And, the neck part 55 b is inserted through the hole 52 a of the chassis 52, the flange part 55 c is contained in the housing space 54, the clamping part 55 a is suspended on the lower part of the chassis 52, and the flange part 55 c is suspended on the upper part of the chassis 52; and the clamper 55 is made vertically movable to the chassis 52.

A cushioning member 57 is made of a ring rubber or the like, and the cushioning member 57 is attached on the support plate 53 inside the housing space 54.

And, the clamper 55 is placed on the upper part, since the magnet 56 is attracted by the magnetic plate 63. In this state, the flange part 55 c is in contact with the cushioning member 57, which functions as a shock absorber when the clamper 55 moves upward.

A drive member 58 is comprised of a drive plate 59 of which one end is rotatably supported and the other end is made vertically movable, a vertically movable motor 60 fixed to the other end of the drive plate 59, and a turntable 61 set about a spindle 60 a of the motor 60, which is vertically movable together with the motor 60.

And, the turntable 61 is provided with a magnetic plate 61 a on the upper side thereof, and when the turntable 61 moves up, the magnet 56 of the clamper 55 makes a transition from attraction with the magnetic plate 63 on the support plate 53 to attraction with the magnetic plate 61 a.

A mount member 62 is made of a metal plate having a hole 62 a. The mount member 62 is placed between the clamper 55 and the turntable 61 to mount a disk D.

Next, the operation of the conventional clamp mechanism for a disk drive will be discussed. In the non-clamped state in FIG. 10, the clamper 55 is located on the upper part where the magnet 56 is attracted by the magnetic plate 63, and the turntable 61 is located on lower part.

First, in this state, the disk D is carried to the drive member 58 from a package or the like by a carrying member (not illustrated), and it is mounted on the mount member 62, as shown in FIG. 10.

Then, a drive motor (not illustrated) is driven to rotate the drive plate 59 so as to raise the other end upward.

And, as shown in FIG. 11, the turntable 61 moves upward with the disk D, and as the turntable 61 approaches the clamper 55, the clamper 55 is detached from attraction with the magnetic plate 63 into attraction with the magnetic plate 61 a on the turntable 61. As a result, the disk D is clamped between the clamper 55 and the turntable 61.

Next, as the motor 60 is driven to rotate the spindle 60 a, the disk D is turned through the turntable 61, thus performing reproduction or recording.

When dismounting the disk D to replace by another, first an eject button is pressed.

Then, the drive motor is driven to move the other end of the drive plate 59 downward, and accordingly the turntable 61 moves down together with the clamper 55.

And, the clamper 55 is suspended such that the flange part 55 c is hung on the bent part 52 b of the chassis 52. In this state, as the turntable 61 moves down further, the turntable 61 with the disk D goes down, and the attraction between the turntable 61 and the clamper 55 is released.

As the result, as shown in FIG. 10, the clamper 55 returns to the state of being attracted to the magnetic plate 63 by the magnet 56, and the turntable 61 is located downward to restore the initial state that the disk D is mounted on the mount member 62.

Then, the disk D is to be carried by the carrying member outside the drive member 58.

In the clamp mechanism for a conventional disk drive thus described, since the clamper 55 is attracted by the magnetic plate 63 in the non-clamped state of the disk D, if the disk drive receives vibrations and shocks, the clamper 55 will be released from attraction with the magnetic plate 63, thus creating displacement of the clamper 55, which is a problem to be resolved.

Further, the conventional clamp mechanism requires the support plate 53, magnetic plate 63, and cushioning member 57, etc., which increases not only the number of the components but also the production cost, and deteriorates the productivity.

SUMMARY OF THE INVENTION

As the first means to solve the aforementioned problems, the clamp mechanism for a disk drive of the present invention is configured with a turntable placed to be vertically movable, a clamper facing to the turntable, which is mounted on a support member such as a chassis so as to be movable in a direction of approaching and detaching from the turntable, and a holding arm that can be engaged with and released from the clamper, wherein the turntable and the clamper are made to be attracted to each other by a magnetic force, the holding arm releases the clamper from a lifted-up state when the turntable is lifted up, a disk is clamped between the turntable and the clamper by attraction of the turntable and the clamper by the magnetic force, the disk is released from being clamped when the turntable is lowered, and the holding arm lifts up the clamper to maintain the lifted-up state of the clamper.

As the second means to solve the problems, the clamp mechanism is configured such that the clamper is attached perforating through the support member, and is provided with a clamping part that underlies the support member and a flange part that overlies the support member, and the holding arm lifts up the flange part to press the flange part to the support member.

As the third means to solve the problems, the clamp mechanism is configured such that the holding arm is provided with a slant part that is slant upward against a face of the disk clamped, and the slant part is engaged with the flange part to lift up the clamper.

As the fourth means to solve the problems, the clamp mechanism is configured such that the holding arm is placed to be swingable in a transverse direction against a moving direction of the clamper.

As the fifth means to solve the problems, the clamp mechanism is configured with, in addition to the first means, a drive gear turned by a motor and a clamp lever turned by the drive gear which is associated with lifting movement of the turntable, wherein the clamp lever is formed integrally with the holding arm.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a drawing to explain the outline of a disk drive relating to the present invention;

FIG. 2 is a plan view of the major part of the clamp mechanism for the disk drive relating to the present invention;

FIG. 3 is a vertical sectional view of the major part of the clamp mechanism for the disk drive relating to the present invention;

FIG. 4 is an enlarged plan view of the major part of the clamp mechanism for the disk drive relating to the present invention;

FIG. 5 is a sectional view taken on by the line 5—5 in FIG. 4;

FIG. 6 is a plan view of the major part to explain the operation of the clamp mechanism for the disk drive relating to the present invention;

FIG. 7 is a vertical sectional view of the major part to explain the operation of the clamp mechanism for the disk drive relating to the present invention;

FIG. 8 is an enlarged plan view of the major part to explain the operation of the clamp mechanism for the disk drive relating to the present invention;

FIG. 9 is a sectional view taken on by the line 9—9 in FIG. 8;

FIG. 10 is a sectional view of the major part of the clamp mechanism for the conventional disk drive; and

FIG. 11 is a sectional view of the major part to explain the operation of the clamp mechanism for the conventional disk drive.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A clamp mechanism for a disk drive of the present invention will now be described with reference to FIG. 1 through FIG. 9. FIG. 1 is a drawing to explain the outline of the disk drive of the present invention, and FIG. 2 through FIG. 9 illustrate the clamp mechanism for the disk drive of the present invention, in which FIG. 2 is a plan view of the major part, FIG. 3 is a vertical sectional view of the major part, FIG. 4 is an enlarged view of the major part, FIG. 5 is a sectional view taken on by the line 5—5 in FIG. 4, FIG. 6 is a plan view of the major part to explain the operation, FIG. 7 is a vertical sectional view of the major part to explain the operation, FIG. 8 is an enlarged plan view of the major part to explain the operation, and FIG. 9 is a sectional view taken on by the line 9—9 in FIG. 8.

Next, referring to FIG. 1, the outline of the disk drive of the present invention will be explained. A disk package P with a plurality of disks D (5 in this embodiment) contained is mounted on a box-shaped enclosure A, so that it can be inserted in and pulled out.

And, a disk drive mechanism K that carries and drives the disk D is installed in the enclosure A so as to be vertically, movable.

And, to operate a disk selection key (not illustrated) arranged on the front face will drive a motor (not illustrated). This motor moves the disk drive mechanism K up and down in the enclosure A, and halts the disk drive mechanism K at a specific position for a selected disk D.

Then, a carrying member (not illustrated) of the disk drive mechanism K is operated, and a specific disk D is carried from the disk package P toward the disk drive mechanism K to be clamped by the disk drive mechanism K.

And, the-disk D is released from being held by the carrying member. And, pressing an operation button will rotate the disk D, thus performing reproduction, recording, and the like.

And then, operating the eject button or the disk selection key will restart the carrying member to hold the disk D. In this state, the disk D is released from the clamped state and returned to the disk package P by the carrying member.

Thus, the disk drive is operated.

Next, the clamp mechanism in the disk drive mechanism K will be discussed referring to FIG. 2 through FIG. 9. A support member 1 made up with a vertically movable chassis assumes a box-shape, which comprises an upper wall 1 a, a step part 1 b bent down, which is provided on the upper wall 1 a, and a hole 1 c provided on the step part 1 b.

And, a clamper 2 is made up with a clamping part 2 a molded of a synthetic resin being a non-magnetic material, a neck part 2 b, a flange part 2 c, and a magnet 3 embedded in the neck part 2 b.

In this clamper 2, the neck part 2 b is inserted through the hole 1 c of the support member 1, the clamping part 2 a underlies the support member 1, and the flange part 2 c overlies the support member 1. Thus, the clamper 2 is mounted on the support member 1 to be vertically movable within a range that the clamping part 2 a and the flange part 2 c are in contact with and suspended by the support member 1.

A clamp lever 4 made of a metal plate includes a clearance hole 4 a provided on the center thereof, a pair of arms 4 b extending in the opposite direction each other, a cam groove 4 c provided near the center thereof so as to surround the clearance hole 4 a, and a U-letter shaped holding arm 5.

As shown in FIG. 3, FIG. 4, and FIG. 5, the holding arm 5 is comprised of a base part 5 a connected to the clamp lever 4, a pair of arms 5 b extending in parallel to each other from both ends of the base part 5 a, which are bent downward, slant parts 5 c extending slant upward, which are formed to connect with the arms 5 b, and suspending parts 5 d being free ends, which are formed to connect with both ends of the slant parts 5 c.

Further, the clamp lever 4 thus constructed is mounted on the upper wall 1 a of the support member 1, so that it is able to rotate about a spindle 6 fixed to the support member 1.

When this clamp lever 4 is mounted, the arms 5 b of the holding arm 5 are disposed such that they can be engaged with and released from the clamper 2 set to the step part 1 b of the support member 1.

That is, the holding arm 5 swings in the traverse direction to the moving direction of the clamper 2 as the clamp lever 4 swings. Thereby, as shown in FIG. 4 and FIG., 5, in the state that the suspending part 5 d is located on the lower part of the flange part 2 c, the holding arm 5 lifts up the clamper 2 to press the clamping part 2 a onto the support member 1. And, as shown in FIG. 8 and FIG. 9, in the state that the suspending part 5 d is released from the lower part of the flange part 2 c, the clamper 2 is able to move freely inside the hole 1 c.

A drive gear 7 possesses a pin 7 a provided on the lower part near the center thereof and a cam groove 7 b formed near the outer part thereof. Disposed to overlie the clamp lever 4, the drive gear 7 has the center part thereof set and supported by a spindle 8 fixed on the upper wall 1 a, so that it can rotate.

Further, the spindle 8 is projected out through the clearance hole 4 a of the clamp lever 4, and owing to the clearance hole 4 a, the clamp lever 4 will not touch the spindle 8 when the clamp lever 4 swings. And, the pin 7 a is inserted in the cam groove 4 c, and accompanied with the rotation of the pin 7 a, the cam groove 4 c is moved. As the result, the clamp lever 4 will swing about the spindle 6, whereby the holding arm 5 will move in the transverse direction against the clamper 2.

A detection member 9 is comprised of a body 9 a and a pair of

switches

9 b, 9 c fixed to the body 9 a. The detection member 9 is attached on the upper wall 1 a by appropriate means.

A switch lever 10 made of a metal plate or the like has a pin 10 a formed on one end and a manipulation piece 10 b formed on the other end. The switch lever 10 has the center thereof attached by a spindle 11 that is fixed on the upper wall 1 a, and thereby it is made rotatable about the spindle 11.

And, when the switch lever 10 is attached, the pin 10 a is inserted in the cam groove 7 b, and the manipulation piece 10 b comes in a state to face the

switches

9 b, 9 c. And, as the drive gear 7 turns, the pin 10 a moves along the cam groove 7 b. As the result, the switch lever 10 turns about the spindle 11, and accompanied with this movement, the manipulation piece 10 b will operate the

switches

9 b, 9 c.

A drive member 12 is comprised of a drive plate 13 whose one end is rotatably supported by the support member 1 and the other end is made vertically movable, a vertically movable turntable 14 mounted on the other end of the drive plate 13, and a pin 15 provided on the side wall of the drive plate 13.

And, the turntable 14 has the upper side made of a magnetic material, and is driven to rotate by a motor (not illustrated).

And, as shown in FIG. 7, when the turntable 14 goes up, the clamper 2 is attracted to the turntable 14 by the magnet 3, and the disk D is clamped between the turntable 14 and the clamper 2.

As shown in FIG. 3 and FIG. 7, a slide member 16 is provided on the side wall of the support member 1, which is able to slide in the cross direction.

The slide member 16 possesses an upper groove 16 a formed on the upper part, a lower groove 16 b formed on the lower part, and a slant groove 16 c that connects the upper groove 16 a and the lower groove 16 b. The pin 15 of the drive member 13 is inserted in these grooves, and the pin 15 is able to move along these grooves.

Further, the slide member 16 has one end suspended by the arms 4 b of the clamp lever 4, and slides in the cross direction with the swing of the clamp lever 4. In accordance with this movement, the pin 15 moves in the vertical direction, whereby the turntable 14 located on the one end of the drive member 12 can be moved up and down.

Further, a motor 17 is fixed to the support member 1, and between a worm gear 18 furnished with the motor 17 and the drive gear 7 is provided an intermediate gear 19, which transmits the rotation of the motor 17 to the drive gear 7.

Next, the operation of the clamp mechanism for a disk drive of the present invention will be discussed. As shown in FIG. 2 through FIG. 5, in the non-clamped state of the disk D, the holding arm 5 is engaged with the lower part of the flange part 2 c of the clamper 2 to lift up the clamper 2, and the drive plate 13 and the turntable 14 are located at a lower position detached from the clamper 2. In addition, the detection member 9 has the switch 9 b operated by the switch lever 10, which indicates a state that the non-clamped state is detected.

Next, in this state, the disk D held by the carrying member is carried between the clamper 2 and the turntable 14.

Then, the motor 17 is driven to rotate the drive gear 7 counterclockwise through the worm gear 18 and the intermediate gear 19, whereby the pin 7 a turns the clamp lever 4 clockwise through the cam groove 4 c, and the holding arm 5 moves in the direction to release the engagement with the clamper 2 and the pin 10 a turns the switch lever 10 clockwise through the cam groove 7 b.

On the other hand, the rotation of the clamp lever 4 slides the slide member 16 forward, effecting to lift the pin 15 upward along the slant groove 16 c, and therefore the turntable 14 is moved up through the drive plate 13.

And, as the rotation of the motor 17 leads to the state shown in FIG. 6 through FIG. 9, the motor 17 stops the rotation; and in this state, the holding arm 5 is released from the engagement with the clamper 2 and the clamper 2 is set free. And, the pin 15 is engaged with the upper groove 16 a to move the turntable upward.

When the turntable 14 is moved up to approach the clamper 2, the clamper 2 set free comes in a state of being attracted to the turntable 14 by the magnet 3, which in consequence leads to a state that the disk D is clamped between the clamper 2 and the turntable 14.

Further, the rotation of the cam groove 7 b of the drive gear 7 turns the switch lever 10 through the pin 10 a, and as the result, the switch 9 c is operated to detect the clamped state of the disk D. This detection will release the disk D from being held by the carrying member.

Next, as the motor (not illustrated) is driven by pressing the operation button, the motor rotates the disk D on the turntable 14, whereby reproduction or recording is to be performed.

And, when dismounting and exchanging the disk D, first the eject button is pressed.

Then, the carrying member holds the disk D first, and the motor 17 rotates in the opposite direction to the above-mentioned direction to rotate the drive gear 7 clockwise.

This rotation turns the clamp lever 4, whereby the arms 5 b of the holding arm 5 start to creep in the lower part of the flange 2 c of the clamper 2, and the slant parts 5 c that are slant against the face of the disk D creep in the lower part to lift up the clamper 2 and also press the clamping part 2 a to the support member 1, thus returning to the original state shown in FIG. 2 through FIG. 5.

Also, this turn of the clamp lever 4 slides the slide member 16 backward, accordingly the pin 15 moves from the upper groove 16 a toward the lower groove 16 b, and accompanied with this movement, the turntable 14 moves downward through the drive plate 13, thus returning to the original state, namely the non-clamped state of the disk D as shown in FIG. 2 and FIG. 3.

Further, the switch lever 10 returns to the original state, and the switch 9 b comes in the operated state, namely, the state of the non-clamped state of the disk D being detected.

The disk D is to be carried back to the disk package P by the carrying member.

Thus, the disk D is clamped or released from being clamped.

Since the clamp mechanism for a disk drive of the present invention is designed to lift up the clamper 2 by the holding arm 5 during the non-clamped state of the disk D, and to maintain the lifted-up state of the clamper 2, it can provide a clamp mechanism without creating displacement of the clamper 2 owing to vibrations, shocks, etc., of the disk drive.

Since the clamp mechanism is made to press the clamping part 2 a of the clamper 2 to the support member 1 by the holding arm 5 raising the flange part 2 c of the clamper 2, it is able to reliably prevent the displacement of clamper 2, and to provide a clamp mechanism with a simplified construction, low production cost, and good productivity.

Also, it can provide a clamp mechanism with a simplified construction and low production cost, since the slant parts 5 c are furnished with the holding arm 5 and the flange part 2 c is made to be raised by the slant parts 5 c.

Further, the holding arm 5 is placed to be swingable in the transverse direction against the moving direction of the clamper 2, and thereby the holding arm 5 can be placed and fixed in flat; therefore, it can provide a thin clamp mechanism.

Furthermore, since the holding arm 5 is integrated with the clamp lever 4, it can provide a clamp mechanism which reduces the number of the components, with a small size, low production cost, and good productivity.

Claims

What is claimed is:

1. A clamp mechanism for a disk drive comprising a turntable disposed so as to be vertically movable, a clamper facing said turntable, said clamper being mounted on a support member so as to be movable in a direction towards or away from said turntable, and a holding arm that can be engaged with and released from said clamper,

wherein said turntable and said clamper are made to be attracted to each other by a magnetic force,

wherein said clamper is movably disposed through an opening in said support member, said clamper being provided with a clamping part that underlies said support member and a flange part that overlies said support member,

wherein said holding arm is provided with a slanted part that is slanted upwardly, said slanted part being configured to engage said flange member so as to raise said clamper into a lifted-up state when said holding arm is engaged with said clamper, said clamping part being pressed against said support member when said clamper is in the lifted-up state, and

wherein said holding arm releases said clamper from the lifted-up state when said turntable is raised, a disk is clamped between said turntable and said clamper by the magnetic force, the disk is released from being clamped when said turntable is lowered, and said holding arm lifts up said clamper to maintain the lifted-up state of said clamper.

2. The clamp mechanism for a disk drive according to claim 1, wherein said holding arm is placed to be swingable in a transverse direction against a moving direction of said clamper.

3. The clamp mechanism for a disk drive according to claim 1, further comprising a drive gear turned by a motor, and a clamp lever turned by said drive gear which is associated with lifting movement of said turntable, wherein said clamp lever is formed integrally with said holding arm.

4. The clamp mechanism for a disk drive according to claim 1, wherein a suspending part is attached to an end of said slanted part, said suspending part being configured to engage a lower surface of said flange member, the lower surface of said flange member being disposed so as to face an upper surface of said support member.

5. The clamp mechanism for a disk drive according to claim 4, wherein the lower surface of said flange member is spaced away from the upper surface of said support member when said clamper is in the lifted-up state.

6. The clamp mechanism for a disk drive according to claim 5, wherein the lower surface of said flange member is disposed against the upper surface of said support member when said clamper is released from the lifted-up state.